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Bibliographic Details
Main Authors: Jain, Paarth, Izmaylov, Artur F., Kjellgren, Erik R.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.14914
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author Jain, Paarth
Izmaylov, Artur F.
Kjellgren, Erik R.
author_facet Jain, Paarth
Izmaylov, Artur F.
Kjellgren, Erik R.
contents Preserving spin symmetry in variational quantum algorithms is essential for producing physically meaningful electronic wavefunctions. Implementing spin-adapted transformations on quantum hardware, however, is challenging because the corresponding fermionic generators translate into noncommuting Pauli operators. In this work, we introduce an exact and computationally efficient factorization of spin-adapted unitaries derived from fermionic double excitation and deexcitation rotations. These unitaries are expressed as ordered products of exponentials of Pauli operators. Our method exploits the fact that the elementary operators in these generators form small Lie algebras. By working in the adjoint representation of these algebras, we reformulate the factorization problem as a low-dimensional nonlinear optimization over matrix exponentials. This approach enables precise numerical reparametrization of the unitaries without relying on symbolic manipulations. The proposed factorization provides a practical strategy for constructing symmetry-conserving quantum circuits within variational algorithms. It preserves spin symmetry by design, reduces implementation cost, and ensures the accurate representation of electronic states in quantum simulations of molecular systems.
format Preprint
id arxiv_https___arxiv_org_abs_2511_14914
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Exact Factorization of Unitary Transformations with Spin-Adapted Generators
Jain, Paarth
Izmaylov, Artur F.
Kjellgren, Erik R.
Quantum Physics
Preserving spin symmetry in variational quantum algorithms is essential for producing physically meaningful electronic wavefunctions. Implementing spin-adapted transformations on quantum hardware, however, is challenging because the corresponding fermionic generators translate into noncommuting Pauli operators. In this work, we introduce an exact and computationally efficient factorization of spin-adapted unitaries derived from fermionic double excitation and deexcitation rotations. These unitaries are expressed as ordered products of exponentials of Pauli operators. Our method exploits the fact that the elementary operators in these generators form small Lie algebras. By working in the adjoint representation of these algebras, we reformulate the factorization problem as a low-dimensional nonlinear optimization over matrix exponentials. This approach enables precise numerical reparametrization of the unitaries without relying on symbolic manipulations. The proposed factorization provides a practical strategy for constructing symmetry-conserving quantum circuits within variational algorithms. It preserves spin symmetry by design, reduces implementation cost, and ensures the accurate representation of electronic states in quantum simulations of molecular systems.
title Exact Factorization of Unitary Transformations with Spin-Adapted Generators
topic Quantum Physics
url https://arxiv.org/abs/2511.14914